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.\" Copyright (c) 2019 Ingo Schwarze <schwarze@openbsd.org>
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.Dd $Mdocdate: August 28 2019 $
.Dt AES_ENCRYPT 3
.Os
.Sh NAME
.Nm AES_set_encrypt_key ,
.Nm AES_set_decrypt_key ,
.Nm AES_encrypt ,
.Nm AES_decrypt ,
.Nm AES_cbc_encrypt
.Nd low-level interface to the AES symmetric cipher
.Sh SYNOPSIS
.In openssl/aes.h
.Ft int
.Fo AES_set_encrypt_key
.Fa "const unsigned char *userKey"
.Fa "const int bits"
.Fa "AES_KEY *key"
.Fc
.Ft int
.Fo AES_set_decrypt_key
.Fa "const unsigned char *userKey"
.Fa "const int bits"
.Fa "AES_KEY *key"
.Fc
.Ft void
.Fo AES_encrypt
.Fa "const unsigned char *in"
.Fa "unsigned char *out"
.Fa "const AES_KEY *key"
.Fc
.Ft void
.Fo AES_decrypt
.Fa "const unsigned char *in"
.Fa "unsigned char *out"
.Fa "const AES_KEY *key"
.Fc
.Ft void
.Fo AES_cbc_encrypt
.Fa "const unsigned char *in"
.Fa "unsigned char *out"
.Fa "size_t length"
.Fa "const AES_KEY *key"
.Fa "unsigned char *ivec"
.Fa "const int enc"
.Fc
.Sh DESCRIPTION
These function provide a low-level interface to the AES symmetric
cipher algorithm, also called Rijndael.
For reasons of flexibility, it is recommended that application
programs use the high-level interface described in
.Xr EVP_EncryptInit 3
and
.Xr EVP_aes_128_cbc 3
instead whenever possible.
.Pp
.Vt AES_KEY
is a structure that can hold up to 60
.Vt int
values and a number of rounds.
.Pp
.Fn AES_set_encrypt_key
expands the
.Fa userKey ,
which is
.Fa bits
long, into the
.Fa key
structure to prepare for encryption.
The number of bits and bytes read from
.Fa userKey ,
the number of
.Vt int
values stored into
.Fa key ,
and the number of rounds are as follows:
.Pp
.Bl -column bits bytes ints rounds -offset indent -compact
.It bits Ta bytes Ta ints Ta rounds
.It 128  Ta 16    Ta 44   Ta 10
.It 192  Ta 24    Ta 52   Ta 12
.It 256  Ta 32    Ta 60   Ta 14
.El
.Pp
.Fn AES_set_decrypt_key
does the same, but in preparation for decryption.
.Pp
.Fn AES_encrypt
reads a single 16 byte block from
.Pf * Fa in ,
encrypts it with the
.Fa key ,
and writes the 16 resulting bytes to
.Pf * Fa out .
The 16 byte buffers starting at
.Fa in
and
.Fa out
can overlap, and
.Fa in
and
.Fa out
can even point to the same memory location.
.Pp
.Fn AES_decrypt
decrypts a single block and is otherwise identical to
.Fn AES_encrypt .
.Pp
If
.Fa enc
is non-zero,
.Fn AES_cbc_encrypt
encrypts
.Fa len
bytes at
.Fa in
to
.Fa out
using the 128 bit
.Fa key
and the 128 bit
initialization vector
.Fa ivec
in CBC mode.
If
.Fa enc
is 0,
.Fn AES_cbc_encrypt
performs the corresponding decryption.
.Sh RETURN VALUES
.Fn AES_set_encrypt_key
and
.Fn AES_set_decrypt_key
return 0 for success, -1 if
.Fa userKey
or
.Fa key
is
.Dv NULL ,
or -2 if the number of
.Fa bits
is unsupported.
.Sh SEE ALSO
.Xr crypto 3 ,
.Xr EVP_aes_128_cbc 3 ,
.Xr EVP_EncryptInit 3
.Sh STANDARDS
ISO/IEC 18033-3:2010
Information technology \(em Security techniques \(em
Encryption algorithms \(em Part 3: Block ciphers
.Sh HISTORY
These functions first appeared in OpenSSL 0.9.7
and have been available since
.Ox 3.2 .
.Sh AUTHORS
.An Vincent Rijmen
.An Antoon Bosselaers
.An Paulo Barreto
